KR100337719B1 - Manual Compression Tool - Google Patents

Abstract

The present invention relates to a crimping tool for crimping electrical connectors. The tool has a compression head, a hydraulic pump, an electric motor, a removable and rechargeable battery, and a control system. The control system includes a printed circuit board for monitoring the voltage of the battery, a trigger, and a pressure sensor of the hydraulic system. The tool is prevented from the start of the crimping operation if the circuit on the printed circuit board senses any improperly low voltage level at which a good crimp cannot be obtained. After a good crimp is obtained, the circuit shuts down the motor for a predetermined time.

Description

Manual compression tool

Background of the Invention

Field of invention

The present invention relates to a tool for compressing an article, in particular a tool for crimping electrical connectors.

Prior art

Hydraulic compression tools with electrical controllers, batteries, signal lights, pressure sensors in hydraulic systems, and systems for reducing pumping of pumps when the pressure in hydraulic systems reaches a predetermined value are disclosed in U.S. Patent Nos. 5,113,679 and 5,152,162. And US Pat. No. 5,195,042. Huskie Tools Inc. of Glendale Heights, Illinois, Illinois, is a rotatable, manual, automatic cable crimper with the trade name ROBO * CRIMP using replaceable and rechargeable battery cartridges. ). The LED battery power level indicator will light when five compression cycles remain. Other related technologies include US Pat. No. 2,998,941; 4,300,28; 4,300,28; No. 4,597,158; 4,914,941; 4,932,237 and; 4,956,992.

Summary of the Invention

According to one embodiment of the invention, the compression device has a compression head, a hydraulic pump, an electric motor, a power source, a sensor and means for stopping the motor operation. The hydraulic pump is operably connected to the compression head and the electric motor is operably connected to the hydraulic pump. The power source is electrically connected to the electric motor to drive the motor. The sensor is provided for sensing the voltage of the power source. The means for stopping the motor is connected to a sensor, the sensor being adapted to stop the motor when it detects any improperly low voltage level of the power source.

According to another embodiment of the invention, a manual crimp tool comprises an electric motor, a battery for driving the electric motor, and means for stopping the crimp operation of the tool. The means for stopping the crimp operation may turn off the tool based on a battery with some improperly low voltage level to obtain a good crimp.

According to another embodiment of the invention, the manual crimp tool comprises a compression head, a drive system and a control system. The drive system is operably connected to the compression head. The drive system has a hydraulic compression system with a pump, an electric motor connected to the pump, and a battery. The control system is operably connected to the motor. The control system has a user triggered actuation trigger, a pressure switch in the hydraulic system, and means for stopping the motor operation. The means for stopping the motor operation is selected to stop the motor when the pressure switch is actuated by some hydraulic pressure in the hydraulic pressure system.

1 is a perspective view showing a tool 10 for crimping an electrical connector on a wire. While the features of the invention are described with reference to one embodiment shown in the drawings, it will be understood that the features of the invention may be embodied in various different forms of embodiments. In addition, any suitable size, shape or material and form may be used.

In FIG. 2, the tool 10 generally comprises a housing 12, a compression head 14, a drive system 16, and a control system 18. The compression head 14 is a well known part of the crimp tool and comprises a ram 20 over a spring load and a frame 22 forming an anvil cross section of the ram. However, any suitable compression head may be provided. A removable crimp die may also be provided.

The drive system 16 generally includes a hydraulic pressure system with a pump 24, an electric motor 26, and a battery 28. The use of a hydraulic pressure system to move the ram is also generally known in the art, as described herein by reference in US Pat. No. 5,113,679. Instead of the manually operated pump described in US Pat. No. 5,113,679, the tool 10 has a motor driven pump 24. In a preferred embodiment, the pump 24 is a direct drive micro-hydraulic pump manufactured by Hydro Rene Leduc, France, with a variable capacity of self-adjusting of five radial pistons. However, other types of pumps can be used. The hydraulic system includes a pressurized hydraulic reservoir 30 in which the pump 24 can receive hydraulic fluid, which can use hydraulic fluid from the compression head 14 when the ram 20 is retracted. In the illustrated embodiment, the motor 26 is a permanent magnet motor that is a high performance circuit oxide device manufactured by G.E.C.-Alsthom. However, in other embodiments, other types of motors may be used. The motor 26 is directly connected to the pump 24 without gear transmission. In the embodiment shown, battery 28 is a 12 volt removable rechargeable nickel-cadmium battery made of 10 sub-C cells with a 1.7 amp-hour charge. However, in other embodiments, other types of batteries or power sources may be used. The battery 28 has a latch 32 that snaps latching and removes the battery from the connection with the housing 12. The battery terminal 34 is located inside the housing 12 to make electrical connection with the connected battery.

The control system 18 includes an actuation trigger 36, a pressure switch or sensor 38 of a hydraulic system, a release trigger 40, and a printed circuit board 42. 3 is a schematic diagram of the electrical system. The actuation trigger 36 generally includes a trigger member 44 and a micro switch 46. The trigger member 44 is pivotally mounted to the housing 12. A spring 48 is used to bias the trigger member 44 to the forward position. When the user presses the trigger member 44, the trigger member 44 has a section 50 adapted to actuate the microswitch 46. The pressure sensor 38 is similar to the pressure sensor described in US Pat. No. 5,113,679 with a spring loaded plunger 39 and a micro switch 41. When the pressure of the hydraulic system reaches a predetermined pressure such as 12,000 psi, the plunger 39 is moved by the hydraulic fluid. A spring (not shown) is pressed and the micro switch 41 is actuated. The trigger microswitch 46 and sensor 38 are connected in parallel between the battery 28 and the circuit 52 on the printed circuit board 42. The printed circuit board 42 generally includes a circuit 52, an electrical connector 54, a relay 56, and two LEDs 58, 59. The two LEDs 58, 9 are connected to a circuit 52. The first LED 58 is an orange / red LED. The second LED 59 is a green LED. The circuit 52 can selectively illuminate two LEDs. The LED protrudes into an opening at the rear end or surface 60 of the housing 12. In another embodiment a relay 56 is mounted above the printed circuit board 42. The relay 56 is preferably a coil relay. The control conductor 62 from the circuit 52 is adapted to excite the coil of the relay to close the relay. The relay 56 is operatively connected between the motor 26 and the battery 28 to act as a switch for turning the motor 26 ON and OFF. The connector 54 connects the battery 28, the trigger 36, and the sensor 38 to the circuit 52 of the printed circuit board 42. Monitor or detect the voltage of the battery 28, detect the operation of the trigger 36 and the sensor 38, based on the voltage sensed by the battery 28 and the state of the trigger 36 and sensor 38 The circuit 52 is formed in a shape suitable for controlling the excitation of the relay 56 coil. The circuit also includes a time delay section 64. The time delay section 64 is formed to prevent excitation of the relay 56 coil during a predetermined length of delay time, such as about 4.5 seconds after the sensor 38 is activated.

In FIG. 4, the operation of the tool is described. The tool is in standby mode when not in use. If the trigger 36 is actuated, the circuit 52 detects this by the signal line 66 and then checks or monitors the voltage of the battery 28. Based on the sensed voltage of the battery 28, the circuit 52 will perform one of three possible actions. If the voltage is below a certain improperly low voltage level, such as 8.75 volts, the circuit 52 turns red to turn the first LED 58 on and places the motor 26 off. Here, the term " presumably inappropriately low voltage level " means a battery voltage level that can drive a motor but is insufficient for good crimp operation. In other words, the battery's power is insufficient to drive the motor to obtain pressure in the compression head for a predetermined pressure of about 12,000 psi. If operated at a certain inappropriately low voltage level with the tool, there is a high probability that bad or insufficient crimp may occur. The present invention is to prevent the tool from starting a crimp cycle if there is a high likelihood that a good crimp cannot be made with the available power of the battery 28. In addition, the red light from the first LED 58 clearly indicates or signals to the user why the tool is not operating due to the low voltage level of the battery 28.

If the sensed battery voltage is less than some improperly low voltage but a good minimum voltage level, such as 9.0 volts, the circuit 52 turns the first LED 58 to ON for orange and Otherwise, it will proceed to its normal operation. As used herein, the term "accurate minimum voltage level" means that the battery voltage level is near some inappropriately low voltage level. The first LED 58 is then illuminated with an orange action to warn the user that the battery voltage is approaching the predetermined inappropriately low voltage level but is not yet low. In a preferred embodiment, the first LED 58 first brightens orange when the tool's about five crimp cycles are raised before any improperly low voltage level is reached.

If the sensed battery voltage is above a good minimum voltage level, the circuit 52 detects whether the pressure sensor 38 is actuated by the pressure of the maximum hydraulic system. If the sensor 38 is actuated, it sends a pulse to the circuit 52 and the time relay section 64 in order not to activate the coils in the relays 56, and before the coils can be re-excited, If it's not working). Even if the user is pressing the trigger member 44, this automatically stops the motor 26 that stops the pump 44. The circuit 52 also turns the second LED 59 ON for green, informing the user of the completion of a good crimp. If the pressure sensor 38 is not activated but the delay time is not completed, the motor is kept OFF by the relay 56. This can occur when the pressure in the hydraulic system is released slightly but before the user prepares the tool with a new crimp cycle. If the delay time is completed, the second LED is turned off and the relay 56 can be reactivated to bring the motor 26 back on.

The control system described above has several features. This monitors or signals the completion of the crimp cycle (by signaling that the maximum pressure of the hydraulic system has been reached) and automatically turns the motor off to charge the battery energy. So a better crimp operation can be performed from the battery charge signal because of the energy charge. The orange light of the first LED warns the user that only a few crimp operations can be performed before the tool stops operating. The control system monitors the battery power and stops the motor if the battery voltage is too low to provide good crimp. So bad crimps are prevented. In addition, the battery is prevented from draining entirely as the control system prevents from starting the battery to drive the motor when the battery voltage is reduced to some inappropriately low voltage level. Therefore, the battery recharges faster and has a longer overall operating life. The control system also signals that the crimp is complete by turning the green LED on.

In other embodiments, any inappropriately low voltage level may be less than or greater than 8.75 volts, and the preferred minimum volt level may be greater than or less than 9.0 volts. Other types of hydraulic sensors can be used. Other types of relays may be used. Other types of circuits can also be used. Many different forms of embodiments can be envisioned from the foregoing features of the invention. Features of the invention can also be used in connector crimp tools and other compression devices.

The foregoing description is illustrative of the invention. Those skilled in the art can envision other variations and modifications without departing from the spirit of the invention. Accordingly, the invention is intended to embrace all such alterations, modifications and variations that fall within the scope of the appended claims.

1 is a perspective view of a crimp tool incorporating features of the present invention.

2 is a cross-sectional view schematically showing the tool body shown in FIG.

3 is a schematic flow diagram of an electrical system used for the tool shown in FIG.

4 is a logic flow diagram of a control system used for the tool shown in FIG.

Explanation of symbols on the main parts of the drawings

10 tool 14 compression head

16: drive system 18: control system

26: electric motor 28: battery

38 sensor 42 printed circuit board

54: electrical connector 56: relay

Claims (20)

Compression head, A hydraulic pump operably connected to the compression head, An electric motor operably connected to the hydraulic pump, A power source electrically connectable to an electric motor for driving the motor; A sensor connected to the power source for sensing the voltage of the power source, And means for stopping motor operation coupled to the sensor to stop the motor operation when the sensor senses any inappropriately low voltage level of the power source. The method of claim 1, The electric motor is operatively connected directly to the pump. The method of claim 1, Wherein said power source is a removable and rechargeable battery. The method of claim 1, And a printed circuit board having a sensor integral with the printed circuit board. The method of claim 4, wherein And a housing, wherein the printed circuit board includes two LEDs extending to the rear surface of the housing. The method of claim 4, wherein And said printed circuit board has means for stopping motor operation integral with the printed circuit board. The method of claim 6, And the means for stopping motor operation comprises a switch between a power source and a motor attached openly by a circuit on a printed circuit board to prevent current from reaching the motor. The method of claim 7, wherein The switch is a coil relay. With electric drive motor, A battery for driving the electric motor, And means for stopping the crimp action of the tool connected between the battery and the electric drive motor by interrupting power supply to the electric drive motor based on a battery having a predetermined inappropriate low pressure level. The method of claim 9, And an actuation trigger further comprising means for stopping the crimp action of the tool comprising a switch and a sensor, wherein the switch is activated when the user actuates the actuation trigger and the sensor causes the battery to be at an inappropriately low voltage level. Manual crimp tool located between the motor and the battery that closes only when it detects that it has a greater voltage. The method of claim 10, The switch and sensor are manual crimping tools integrated on a single printed circuit board. The method of claim 11, The switch is a coil relay, and the coil of the relay is excited by a circuit on the printed circuit board only when the trigger is activated, and the sensor causes the battery to draw a voltage greater than some improperly low voltage level at the beginning of the tool cycle. Manual crimp tool to detect having. The method of claim 9, And a means for stopping the crimp operation of the tool when the hydraulic system and the hydraulic pressure system of the tool reach the pressure of the predetermined hydraulic system. The method of claim 13, And further comprising a printed circuit board and a switch, wherein the means for stopping the crimping operation of the tool comprises a pressure sensor electrically connected to the printed circuit board, the switch being capable of detecting the pressure of the battery and the predetermined hydraulic system. Hand crimp tool between motors when open. The method of claim 13, The printed circuit board includes a circuit for providing a predetermined delay time after the sensor senses the pressure of the predetermined hydraulic system before the crimp operation of the tool is resumed. With compression head, A hydraulic pressure system operably connected to the compression head, a hydraulic pressure system with a pump, an electric motor connected to the pump, a drive system with a battery, an operation trigger operably connected to the motor, and a user operated trigger; And a control system having a pressure switch of a hydraulic system and means for stopping the motor operation when the hydraulic switch is operated by a predetermined hydraulic pressure of the hydraulic system. The method of claim 16, The control system is a manual crimping tool having a printed circuit board having a relay switch between a battery and a motor. The method of claim 17, Said trigger and pressure switch being connected in parallel between the battery and the printed circuit board. The method of claim 17, And a housing further comprising a housing, wherein the printed circuit board includes two LEDs extending out of the rear surface of the housing. The method of claim 16, Further comprising a housing, wherein the trigger includes a microswitch and a trigger member, the trigger member being pivotally mounted to the housing to operate the microswitch when the member is pressed.